Student Learning Goals:
<br>◆ Learn detection methods and their principles
<br>◆ Learn analytical methods and their principles
<br>◆ Learn device application
<br>
<br>Handouts: may be downloaded by the student.
<br>
<br>Assignments and Grading (subject to revision):
<br>◆ Class participation: 10%
<br>◆ Midterm exam: 30%
<br>◆ Final exam: 50%
<br>◆ Final report 10%
<br>
<br>Contact: 森川響二朗 助教授 / Kyojiro Morikawa, Assistant Professor 
<br>(morikawa@icl.t.u-tokyo.ac.jp)
<br>Q95;
<br>Contents:
<br>1. Concept of detection
<br>	1.1	What we detect?
<br>	1.2	How we detect molecules?
<br>	1.3	How we specify molecules?
<br>
<br>2. Electrometric detection
<br>	2.1	Ion mobility, liquid impedance
<br>	2.2	Conductivity analysis
<br>	2.3	Redox reaction, Nernst equation
<br>	2.4	Voltammetry
<br>	2.5	Voltage-difference analysis
<br>	2.6	Application: Fuel cell device, etc.
<br>
<br>3. Thermometric detection
<br>	3.1	Thermal conductivity analysis
<br>	3.2	Differential thermal analysis
<br>	3.3	Thermogravimetric analysis
<br>
<br>4.Molecular mass-metric detection
<br>	4.1	Mass spectroscopy
<br>	4.2	Methods for mass separation
<br>	4.3	Methods for ionization
<br>
<br>5. Molecular separation and recognition
<br>5.1	Physicochemical methods
<br>			a) Electrophoresis
<br>			b) Liquid chromatography
<br>			c) Gas chromatography
<br>5.2	Biochemical methods
<br>			a) Immunoassay
<br>			b) Biosensor
<br>
<br>6. Design of device
<br>	6.1	Combination of detector and molecular recognition methods
<br>	6.2	Example